2018
DOI: 10.1155/2018/6497340
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The Rayleigh Fading Channel Prediction via Deep Learning

Abstract: This paper presents a multi-time channel prediction system based on backpropagation (BP) neural network with multi-hidden layers, which can predict channel information effectively and benefit for massive MIMO performance, power control, and artificial noise physical layer security scheme design. Meanwhile, an early stopping strategy to avoid the overfitting of BP neural network is introduced. By comparing the predicted normalized mean square error (NMSE), the simulation results show that the performances of th… Show more

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Cited by 62 publications
(34 citation statements)
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References 24 publications
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“…[451] Learning to communicate over an impaired channel AE + radio transformer network Ye et al [452] Channel estimation and signal detection in OFDM systsms. MLP Liang et al [453] Channel decoding CNN Lyu et al [454] NNs for channel decoding MLP, CNN and RNN Dörner et al [455] Over-the-air communications system AE Liao et al [456] Rayleigh fading channel prediction MLP Huang et al [458] Light-emitting diode (LED) visible light downlink error correction AE Alkhateeb et al [444] Coordinated beamforming for highly-mobile millimeter wave systems MLP Gante et al [443] Millimeter wave positioning CNN Ye et al [506] Channel agnostic end-to-end learning based communication system Conditional GAN architecture achieves near-optimal accuracy, while requiring light computation without prior knowledge of Signal-to-Noise Ratio (SNR). Yan et al employ deep learning to solve a similar problem from a different perspective [447].…”
Section: Deep Learning Driven Signal Processingmentioning
confidence: 99%
“…[451] Learning to communicate over an impaired channel AE + radio transformer network Ye et al [452] Channel estimation and signal detection in OFDM systsms. MLP Liang et al [453] Channel decoding CNN Lyu et al [454] NNs for channel decoding MLP, CNN and RNN Dörner et al [455] Over-the-air communications system AE Liao et al [456] Rayleigh fading channel prediction MLP Huang et al [458] Light-emitting diode (LED) visible light downlink error correction AE Alkhateeb et al [444] Coordinated beamforming for highly-mobile millimeter wave systems MLP Gante et al [443] Millimeter wave positioning CNN Ye et al [506] Channel agnostic end-to-end learning based communication system Conditional GAN architecture achieves near-optimal accuracy, while requiring light computation without prior knowledge of Signal-to-Noise Ratio (SNR). Yan et al employ deep learning to solve a similar problem from a different perspective [447].…”
Section: Deep Learning Driven Signal Processingmentioning
confidence: 99%
“…On the issue of fading channel prediction, standard predictive neural networks with full connections have been evaluated in various contexts in single-subcarrier settings, e.g. Ding and Hirose (2014) [21], Liao et al (2018) [22], Jiang andSchotten (2019, 2020) [23], [24], and Yuan et al (2020) [25], with [25] employing an extra CNN channel classifier to identify patterns in the autocorrelation function of the channel prior to applying the actual predictor. Overall, while the Kalman filtering scheme is based on linear models and parametrised probability assumptions, predictive neural networks incorporate nonlinearities and no specific interpretation (such as Kalman gain or conditional state variance) is imposed on their model parameters.…”
Section: A Background and Related Workmentioning
confidence: 99%
“…The network performance prediction and related deep learning technologies for solving mobile networking problems are summarized in [10], and the case studies and intelligent decision-making use of machine learning are described in [11]. The prediction of channel state information (CSI) was proposed in [10][11][12][13][14]. CSI is predicted by the position of the terminal, temperature, humidity, and weather in [12].…”
Section: Introductionmentioning
confidence: 99%